An auxiliary battery storage device stores an auxiliary battery that is used for performing cell balancing to a main battery adopted in an electric vehicle or supplying power to the main battery having low state of charge (SOC). The auxiliary battery storage device includes a case body formed in a box shape with a top portion that is open and an inner space in which the auxiliary battery is stored; a case body cover coupled to the case body to open or close the top portion of the case body; a terminal connection member fixed to an inner surface of the case body cover to contact a power terminal of the auxiliary battery when the top portion of the case body is closed by the case body cover; and a power cable configured to extend from the terminal connection member to the main battery.

The present invention relates to a cell balancing system and method, and more particularly, to a cell balancing system and method capable of supplying a charging voltage through two separately configured charging voltage sources and stably performing cell balancing by supplying a proper charging voltage to a corresponding cell through an individually configured switch in each cell, when the cell balancing is necessary.

The invention provides an uninterruptible power supply, which comprises a battery management circuit and a control circuit. The battery management circuit is electrically coupled to each battery of at least one battery string for measuring the voltage of each battery. When the battery strings discharge, the control circuit obtains the voltage of each battery through the battery management circuit to calculate the discharge current of each battery, and determines whether there is any measured voltage having dropped to an EOD voltage corresponding to a discharge current of a corresponding battery. When the determination result is positive, the control circuit controls the uninterruptible power system to stop the discharging of at least one battery string in which there is at least one measured voltage having dropped to an EOD voltage corresponding to a discharge current of a corresponding battery. Furthermore, a corresponding battery management apparatus is also provided.

A computer-implemented system and method for balancing battery cells of a multi-cell battery, the system comprising a processor configured to determine a state of charge for each battery cell, generate a probability table for all of the battery cells based on a difference between the state of charge for each battery and a mean state of charge, select one of the battery cells via probabilistic selection according to the probability table, and generate an instruction for adjusting a charge of the selected battery cell.

A battery pack receives a charging current from a charger via a power line. The battery pack includes a battery management unit and a transmitting unit. The battery management unit is coupled to a plurality of battery cells and is operable for acquiring data associated with the battery pack. The transmitting unit is coupled to the battery management unit and is operable for transmitting the data to the charger via a power line.

A protective device connected between an external terminal provided in an energy storage apparatus and a power cable extending from a vehicle, the protective device includes a current interruption device that interrupts electric conduction between the vehicle and the energy storage apparatus in response to a command of a CPU in a battery management device provided in the energy storage apparatus.

A method for operating electrical energy stores, in particular for use in motor vehicles, the method including: ascertaining a charge state of a first energy store with the aid of an evaluation unit, ascertaining a charge state of a second energy store with the aid of an evaluation unit, ascertaining an instantaneous power demand with the aid of an evaluation unit, adapting an operation of at least one energy store on the basis of the ascertained charge states and the ascertained instantaneous power demand with the aid of a control unit, the adapting being made using at least one semiconductor switch, in particular bidirectionally.

In an embodiment, a system for balancing input current for power supplies a voltage detector configured to detect an input voltage to a power supply of a plurality of different power supplies. The system further includes one or more circuit elements configured to adjust one or more properties of the one or more circuit elements based at least in part on the detected input voltage in an attempt to maintain a consistent current input across the plurality of different power supplies.

A charger includes a power output interface configured to output a charging signal, a signal interface configured to acquire charging information of a battery, a balance charging interface configured to perform balance charging control over sets of battery cores of the battery, and a control circuit electrically connected to the power output interface, the signal interface, and the balance charging interface. The control circuit is configured to select the signal interface and/or the balance charging interface to perform charging control over the battery.

A battery cell system and an associated monitoring system is provided which includes at least an anode, a cathode, a separator formed from a base layer, first and second contacts and a reference component. The anode and cathode are disposed in a lithium ion non-aqueous solution within a housing. The base layer of the separator includes a first side and a second side. The base layer is operatively configured to separate the anode and the cathode within the housing. The first contact of the separator is affixed to the first side of the base layer between the base layer and an anode. The second contact is affixed to the second side of the base layer with the reference component disposed on the second contact.